Abstract: A method for automatic image optimization in ultrasound imaging of an object is provided. The method includes transmitting a first ultrasound signal into the object, wherein the signal has a plurality of first signal parameters. The method also includes receiving a first set of electrical signals representing reflections of the first ultrasound signals from the object and processing the first set of electrical signals into a first image. The method evaluates an image quality cost function for the first image to produce a first image quality metric and determines a second plurality of signal parameters based upon the first image quality metric. Similarly, the method includes transmitting a second ultrasound signal into the object, wherein the signal has the second plurality of signal parameters and receiving a second set of electrical signals representing reflections of the second ultrasound signal from the object and processing the second set of electrical signals into a second image.

Abstract: This disclosure describes methods for detecting early stages of disease, in particular carpal tunnel syndrome, by using cooperative ultrasound techniques. In a particular embodiment, a grayscale ultrasonogram may be used to detect local anatomical features within the carpal tunnel by physically moving a tendon and identifying the corresponding feature on the ultrasonogram display device. A high-resolution color Doppler ultrasound device may then be used to interrogate features of anatomy surrounding the tendon for disease. In a particular embodiment, the color Doppler ultrasound device may be used to measure the velocities of the tendon and surrounding anatomy, in particular the sub-synovial connective tissue; the resultant data may be used to quantify certain anatomical anomalies, indicative or non-indicative of carpal tunnel syndrome.

Abstract: A method for detection of the position and orientation of the tip of a needle-like medical device inserted into a tissue of a patient using scanning apparatus. The method obtains a first scan of the tissue correlating the needle-like medical device with a plurality of needle-like templates, each one having a different angular orientation to obtain an feature image of the device; obtains eigenvalues and an eigenvector of image to obtain the angular orientation of an image plane for a subsequent scan; transforms the orientation of the device in the determined image plane into scanning system reference coordinates with the longitudinal axis of the needle like device having a predetermined orientations with respect to the reference coordinate system; and makes observations along each of a sequence of lines transverse to the longitudinal axis of the image of the device in the determined plane to detect the tip of the device.

Abstract: A position detecting apparatus having a magnetic field generator that generates a position detecting magnetic field having variable strength, a position calculator that acquires magnetic information relating to the position detecting magnetic field at a position where a detected object is present, and calculates a position of the detected object based on the magnetic information, a range calculator that calculates a possible existence range in which the detected object can be present at a second time instant when a predetermined time has passed since a first time instant, based on the position of the detected object at the first time instant calculated by the position calculator, and a magnetic-field strength controller that controls a strength of the position detecting magnetic field so that the position detecting magnetic field having a strength detectable by the detected object-is generated within the possible existence range.

Abstract: A system and method are disclosed, which combine image data of a patient, such as images of the patient's GI tract, with rating mucosal damage. According to some embodiments of the present invention the system and method are able to assess a patient's GI tract condition, to monitor mucosal healing in a patient's GI tract, preferably, the small bowel (SB) mucosa and/or to differentiate between different pathological conditions. The system and method of the invention can provide a value or score arrived at by assigning a grade relating to one or more predetermined parameters.

Abstract: An image diagnostic system controls a probe to perform rotational and axially-moving scanning within a body cavity and to acquire reflected signals through the probe. Based on the acquired reflected signals, the system forms and outputs tomographic image of the body cavity and biotissue surrounding the body cavity. The system is provided with a detection unit which detects a direction of movement of the probe in the axially-moving scanning and a control unit which controls the rotational speed of the probe in the rotational scanning. The control unit includes a determination unit which determines whether or not the rotational speed of the probe is to be changed upon detection of movement of the probe toward the distal direction within the body cavity, and changes the rotational speed of the probe upon determination of a change at the determination unit.

Abstract: A position detection apparatus and a medical-device-position detection system that have improved position detection accuracy are provided by setting high amplification for the position detection apparatus. The position detection apparatus includes a circuit that has at least one embedded coil (10a) and that is provided inside an object (10) to be detected; a first magnetic-field generating unit (11) for generating a first magnetic field in the region where the embedded coil (10a) is disposed; a magnetic-field detecting unit (5, 12) for detecting an induced magnetic field generated at the embedded coil (10a) by the first magnetic field; and a second magnetic-field generating unit (23) for generating a second magnetic field having a phase substantially opposite to the phase of the first magnetic field.

Abstract: Provided is a method for rapid, 3D, dynamic, projection reconstruction bilateral breast imaging using simultaneous multi-slab volume excitation and radial acquisition of a contrast enhanced bilateral image, in conjunction with SENSE processing, using k-Space Weighted Image Contrast (“KWIC”) filtering and multi-coil arrays for signal separation in an interleaved bilateral MR bilateral breast scan that uses conventional Cartesian sampling without parallel imaging. Software was developed for the reconstruction, modeling contrast kinetics using a heuristic model, display by parametric mapping and viewer/analysis of the multidimensional, high frame-rate bilateral breast images.

Abstract: The attenuation and other optical properties of a medium are exploited to measure a thickness of the medium between a sensor and a target surface. Disclosed herein are various mediums, arrangements of hardware, and processing techniques that can be used to capture these thickness measurements and obtain three-dimensional images of the target surface in a variety of imaging contexts. This includes general techniques for imaging interior/concave surfaces as well as exterior/convex surfaces, as well as specific adaptations of these techniques to imaging ear canals, human dentition, and so forth.

Abstract: The attenuation and other optical properties of a medium are exploited to measure a thickness of the medium between a sensor and a target surface. Disclosed herein are various mediums, arrangements of hardware, and processing techniques that can be used to capture these thickness measurements and obtain three-dimensional images of the target surface in a variety of imaging contexts. This includes general techniques for imaging interior/concave surfaces as well as exterior/convex surfaces, as well as specific adaptations of these techniques to imaging ear canals, human dentition, and so forth.

Abstract: Disclosed is a living body measurement apparatus including: a first light source placed on the surface of the skin in a living body and radiating a first light in a visible light wavelength range onto the surface of the skin; a second light source placed on the surface of the skin and radiating a second light in a near-infrared wavelength range onto the surface of the skin; an optical detector placed on the surface of the skin at a predetermined distance from the first and second light sources to detect, as an electric signal, first or second detection light penetrating up through the skin and inputted thereto among the radiated first or second light; and a controller for sequentially driving the first and second light sources.

Abstract: The attenuation and other optical properties of a medium are exploited to measure a thickness of the medium between a sensor and a target surface. Disclosed herein are various mediums, arrangements of hardware, and processing techniques that can be used to capture these thickness measurements and obtain three-dimensional images of the target surface in a variety of imaging contexts. This includes general techniques for imaging interior/concave surfaces as well as exterior/convex surfaces, as well as specific adaptations of these techniques to imaging ear canals, human dentition, and so forth.

Abstract: The ultrasonic imaging apparatus comprises an ultrasonic probe, a detecting part, a position analyzing part, a display control part, a display part, and a storage part. The detecting part is mounted on the ultrasonic probe operable to detect a part of a prescribed pattern formed on an ultrasonic low attenuation medium. In the storage part, the prescribed pattern formed on the ultrasonic low attenuation medium has been preliminarily stored. Upon receipt of detection results from the detecting part, the position analyzing part specifies the position of a part of the detected pattern on the prescribed pattern by referring to the prescribed pattern stored in the storage part. The display control part controls the display part to display the positional relation between the ultrasonic probe and the subject to be examined regarding the position of a part of the prescribed pattern that has been detected as the position of the ultrasonic probe.

Abstract: An image diagnostic system controls a probe to perform radial scanning within a body cavity and to acquire reflected signals through the probe. The system produces data based on the signals, constructs and outputs tomographic images of the body cavity and biotissue surrounding the body cavity. The system includes an extraction unit for extracting portions of the produced data on the basis of a frame rate upon successively outputting the tomographic images, and a first output control unit for forming, based on the extracted data, real time tomographic images of the body cavity and biotissue which are outputted in real time during radial scanning. A storage device stores the produced data, and a second output control unit forms, subsequent to the radial scanning, tomographic images of the body cavity and biotissue based on the stored data which are then outputted.

Abstract: The present invention relates to a method and apparatus for visualizing movements of an object, preferably the movements of blood vessels during the cardiac cycle. The method includes scanning the object by at least a two dimensional ultrasonic image scanning apparatus at discrete acquisition times to acquire a data set by using surface reconstruction and/or volume rendering techniques. Next, the three-dimensional data set is partitioned into a plurality of volume units, wherein each volume unit has a unit surface. The method further includes calculating the change of volume of each volume unit over the acquisition times to obtain level information of each corresponding unit surface over time, and displaying the three-dimensional data set with its level information over time.

Abstract: Systems and methods for blood flow and perfusion measurement using complex amplitude modulation of MRI pulses are presented. In exemplary embodiments of the disclosed subject matter, inflowing arterial spins can be modulated using a complex modulation function having certain mathematical properties in the frequency domain, such as, for example, a pseudo-random sequence. In exemplary embodiments of the disclosed subject matter the mathematical properties of such complex modulation functions can be used to measure individual transit times by deconvolving them from a series of acquired images. In exemplary embodiments of the disclosed subject matter images can be acquired at the same rapid rate as arterial modulation, and transit time distribution in the imaged tissue can be determined as part of a single integrated acquisition.

Abstract: A wound treatment system includes a distribution manifold, a reduced pressure source, a fluid delivery source, and an ultrasonic energy transducer. Reduced pressure and fluid delivery may be applied to the wound through the distribution manifold. The ultrasonic energy transducer is configured to deliver ultrasonic energy to the wound to debride the wound. The ultrasonic energy transducer may be either a piezoelectric transducer or a surface acoustic wave device. The ultrasonic energy transducer may be placed adjacent to the distribution manifold to deliver ultrasonic energy directly to the wound or may be coupled to an acoustically-conducting membrane positioned between the distribution manifold and the wound.

Abstract: A position detecting apparatus includes a linear magnetic-field generator that generates a linear magnetic field in an area inside the subject; a diffuse magnetic-field generator that generates a diffuse magnetic field having position dependency on magnetic field direction in the area; a magnetic-field line orientation database in which a correspondence between magnetic field direction and position of the diffuse magnetic field in a reference coordinate axis is recorded; an orientation calculator that calculates orientation information of a body-insertable device introduced into a subject in the reference coordinate axis based on linear magnetic-field information and the earth magnetism direction; and a position calculator that calculates a magnetic field direction of the diffuse magnetic field at the position of the body-insertable device based on the linear magnetic-field information, orientation information, and diffuse magnetic-field information, and calculates the position of the body-insertable device b

Abstract: A method for obtaining a distribution of a stiffness property in tissue includes applying a plurality of loadings to the tissue, obtaining a plurality of two-dimensional (2-D) imaging projections of the tissue from different directions, measuring a force resulting from one of the plurality of loadings, measuring from at least one of the plurality of 2-D imaging projections a displacement of the tissue in response to the force, obtaining an initial set of input parameters for an estimated stiffness property of the tissue, and solving iteratively for the stiffness property using a computer.